KR101596367B1 - Fitting for a vehicle seat and vehicle seat - Google Patents

Abstract

The present invention relates to a fitting for a vehicle seat, in particular an automobile seat, comprising a first fitting part (11), a second fitting part (12) and an eccentric part rotatably supported, (17) and a spur gear (16) on the second fitting part which engage the toothed ring so that the two fitting parts (11, 12) are in transmission connection with one another and are rotatably supported The eccentric portion rotates in the circumferential direction to drive the relative rolling movement of the spur gear 16 and the ring gear 17 and the outer side of the eccentric portion is arranged in a radial direction in a planar bearing bushing 28, Is arranged on the bearing seat (29), in particular on the collar (29) of the first or second fitting part (11, 12), the plane bearing bushing (28) To the bearing seat 29 Plane travel is plastic-coated side of the bearing bushing (28).

Description

FIELD OF THE INVENTION [0001] The present invention relates to a seat for a vehicle,

The present invention relates to a fitting for a vehicle seat having a first fitting member and a second fitting member and a rotatably supported eccentric portion, wherein a toothed ring is formed on the first fitting member and a toothed A wheel is formed which engages the toothed ring so that the two fitting members are connected to each other in a gear system fashion and the rotatably supported eccentric part drives the relative rolling motion of the toothed wheel and the toothed ring Which eccentric portion is arranged in a plane bearing bushing whose outer side in the radial direction is arranged in the bearing seat, in particular in the extruded collar of the first or second fitting member.
The present invention also relates to a vehicle seat having such fittings.

DE 44 11 214 A1 discloses a fitting for a vehicle seat in which a flat bearing bush comprising a rolled multilayer material is precisely punched by a calibrated calibration mandrel and is screwed into a bearing seat of a hardened toothed wheel, Lt; / RTI > In this scale calibration operation, a pre-tension is generated in the radial direction between the flat bearing bush and the toothed wheel, which acts against axial drifting. In automotive manufacturing, there has been a constant need for techniques to further increase strength while maintaining or reducing structural space, thus requiring thinner planar bearing bushings. For the otherwise hardened components in the path of the force of the fitting, the rolled plain bearing bushes constitute the softest component of the fitting. The resulting deformation of the flat bearing bush in the event of a collision leads to a loss of coverage and consequent loss of performance in the tooth arrangement in the region of tooth engagement between the fitting members. The smaller bearing thickness of the planar bearing bush induces less deformation and consequently less loss of performance action. However, in the case of thin wall thicknesses, in particular wall thicknesses of less than 1 mm, there is a problem in that the 'generation of radial preliminary tension', which is required for preventing axial drifting as described above, is no longer ensured.
Pressed plain bearing bushes of a general type of fitting are also disclosed in DE 20 2009 007 520 U1.
DE 10 2010 013 091 A1 describes a positive locking fastening area as an axial fastening member of a flat bearing bush which forms before or after the flat bearing bush is pressed and forms an undercut with respect to the bearing diameter of the toothed member, It prevents the movement of the plain bearing. The formation of the bond region is limited by the ability of the planar bearing bushing material to be shaped. The high tolerance requirements for the bearing position require relatively complex molding processes.
Due to the high level of forces generated during the introduction of the flat bearing bush into its bearing seat by pressing or deformation, the flat bearing bush must be constructed as rigid as possible. The use of planar bearing bushes comprising material rolling over 360 ° with unconnected opposite ends is therefore not possible, or only to a very limited extent. The ends are therefore connected to one another in most applications, in particular clinically or laser-welded.
The fitting disclosed in DE 10 2008 028 094 A1 provides that a planar bearing ring externally placed on the extruded collar is connected to this extruded collar in a materially integrated manner by welding, adhesive bonding, brazing or pressing. This material integration connection is necessary because of the problem that the planar bearing ring arranged on the outer side of the extruded collar, in particular the slotted rings, can not be calibrated, and this problem can be avoided between the flat bearing ring and the extruded collar Sufficient tensile forces can not be created for the engagement to be secured by frictional forces.
US 2011 0169312 A1 discloses a non-slotted planar bearing ring that is anchored to the extruded collar of a fitting member in a non-positive locking manner, the inner diameter of which is smaller than the extruded collar outer diameter.
Particularly the plastic coated running side of the flat bearing rings described in the last two publications mentioned is on the outer periphery thereof. In contrast, the plain bearing bushes to be pressed have a running side on the inner circumferential surface.
The welding method known from DE 20 2009 007 520 U1 for shaft / bush connection is not used for plastic coated flat bearing bushes with a thin wall thickness.

It is an object of the present invention to improve fittings of the type mentioned in the introduction, and in particular to provide the possibility of using flat bearing bushings with a low wall thickness and a plastic coating on the running face as planar bearings. It is also intended to enable the elimination of expensive clinching or laser welding operations on the gaps between the opposite ends of the rolled planar bearing bushings when required for assembly and work intensity. To ensure the outward pressing forces of the flat bearings from the bearing seats, high tolerance requirements for the flat bearing bushes and bearing seats should not be required.

This object is achieved by a fitting having a first fitting member, a second fitting member and an eccentric portion rotatably supported in accordance with the present invention, wherein a toothed ring is formed on the first fitting member and a toothed ring is formed on the second fitting member, The machined wheel is formed and engaged with the toothed ring so that the two fitting members are connected to each other in a gear system fashion and the rotatably supported eccentric part drives the relative rolling motion of the toothed wheel and the toothed ring The eccentric portion being arranged in a plane bearing bushing whose outer side in the radial direction is arranged in the bearing seat, in particular in the extruded collar of the first or second fitting member, and the plane bearing bush is arranged in a laser welding Wherein the planar bearing bush has a wall thickness of less than < RTI ID = 0.0 > 1mm, < / RTI & Bush running the ring side is coated with a plastic material.
It is possible to construct plastic coated flat bearings with such thin wall thicknesses because the flat bearing bushes are connected to the bearing seat in a materially integrated manner by laser welding. The wall thickness of the flat bearing bushes need not be configured for the required friction forces that must be applied between the bearing seats and the flat bearing bushes. Material integration of the flat bearing bushes in the bearing seats also allows the opposite ends of the flat bearing bushes to remain unconnected because of the lower requirements for frictional forces, Can also be less. Compared to the pure frictional engagement link between the bearing seat and the planar bearing bush, the requirements for the tolerances of each planar bearing component are less.
Compared to other welding methods, less energy is transferred to the fitting member, the bearing seat, and the flat bearing bush during the laser welding operation, resulting in less thermal distortion of the components. The running sides of the planar bearing bushes can be coated with a plastic material because the thermal loading of the laser welding motion is correspondingly small so that the coating is not thermally destroyed.
In a preferred embodiment, the bearing seats are provided on one of the two fitting members and the flat bearing bushes are connected to a laser welding seam in the region of the end face of the plane bearing bush, which is the other of the two fitting members To the bearing seat. This arrangement can be used particularly well during the welding operation. The laser weld seam may in this example be configured to break several times, particularly around the circular perimeter of the flat bearing bush, or it may be configured as a peripheral laser weld seam providing a particularly high level of strength. Three tacking positions distributed at an angle of 120 [deg.] Across the plane bearing bush are found to be particularly cost effective.
Preferably, the bearing seat is an extruded collar of the first or second fitting member. This single piece construction constitutes a very cost effective bearing seat.
A bearing seat comprising a separate sleeve secured to the first or second fitting member is suitable for manufacturing a fitting member configuration kit. The cost intensive basic geometric shape for the fitting members at the sides of the tools is thereby the same for all deformations. Deformation within the range of the bearing seats, in particular bearing seats of different axial lengths, can be produced by different sleeves. Extreme bearing sheet geometries that can not be produced as an extruded collar can also be manufactured in a simple manner by use of sleeves.
It is preferable to use flat bearing bushes having cylindrical basic shapes and with their opposite ends facing each other in the unconnected state. Elimination of the connection of the ends, such as can be done, for example, by clinching connections, significantly reduces the cost of the flat bearing bush.
Planar bearing bushes having a wall thickness of approximately 0.5 mm are particularly suitable for reducing the component volume of the fittings and for increasing the strength of the fittings.
A further increase in the strength against axial movement of the flat bearing sleeve in the axial direction from the bearing seat is achieved by turning over one of the two axial ends of the flat bearing bush in the radially outward direction.
Whereby the flat bearing bush can be axially supported on the bearing seat. Flipping can be carried out by methods known to those skilled in the art, in particular in a preferred manner by a beading operation.
By means of the planar bearing edges inverted on both axial sides, axially extending positions can be created, i.e. one of the fitting members for adjacent components, such as the carrier being moved on the relative side, or two Axial bearing surfaces may be generated that reduce the operating torque of the fitting (to minimize friction) by ensuring the support function of the fitting members. With this embodiment, one of the two ends can only be turned over after the plane bearing bush is introduced into the bearing seat. However, precisely one of the two inverted ends acts as an axial stop when the flat bearing bush is already turned over before it is introduced into the bearing seat and consequently the planar bearing bush is introduced into the bearing seat.
The invention is described in more detail below with reference to the five embodiments shown in the Figures.

1 is a perspective view of the first embodiment,
2 is a schematic view of a vehicle seat having fittings,
Figure 3 is a view showing an axial section through the first embodiment,
4 is a perspective view of the second embodiment,
5 is a view showing an axial section through the second embodiment,
Figure 6 is a view showing an axial section through the third embodiment,
7 is a plan view of the first fitting member of the fourth embodiment,
8 is a view showing an axial section through the first fitting member of the fifth embodiment.

The automotive vehicle seat 1 has a back 4 that can be adjusted in terms of its inclination relative to the seat member 3 and the seat member 3. [ The driving shaft 7 horizontally arranged in the transition region between the seat member 3 and the back 4 is manually rotated by handwheel 5 or rotated by hand, It is motor driven by electric motor. On both sides of the vehicle seat 1, the drive shaft 7 is engaged with the fitting 10 in a rotationally fixed manner. In this example, in the circumferential direction of the drive shaft 7, a small free extension angle can be provided between the drive shaft 7 and one of the fittings 10 for tolerance compensation. The drive shaft 7 defines the axis of the cylindrical coordinate system used for the direction indications used below. The direction indications remain valid regardless of any minor inaccuracies resulting from relative wobbling motion between the individual components of the fitting 10 as described below and the deviations due to manufacturing related component tolerances Quot; is intended to be interpreted in a broad sense that also encompasses < / RTI >
The fitting 10 has a first fitting member 11 and a second fitting member 12, which can be rotated relative to each other. By the assembly of the fitting 10, the first fitting member 11 is firmly connected to the structure of the back 4 of the vehicle seat 1, that is, it is fixed to the backrest member. The second fitting member 12 is then firmly connected to the structure of the sheet member 3, i. E., Secured to the sheet member. However, the relationships of the fitting members 11 and 12 can also be reversed, that is, the first fitting member 11 will then be secured to the seat member and the second fitting member 12 will be secured to the backrest. The fitting 10 is located in the force path between the backrest and the seat member, and for this reason the two fitting members 11 and 12 comprise a metal, preferably a steel.
The fitting 10 is configured as a gear fitting wherein the first fitting member 11 and the second fitting member 12 are connected to each other by a gear mechanism for regulation and anchoring, 809 C1, the disclosure of which is hereby expressly incorporated herein by reference.
1 and 3), the first fitting member 11 has a first flange region 11a and the second fitting member 12 has a second flange region 12a, Shaped area of the fitting members 11 and 12 and is used for connection to the seat member 3 and the back 4, respectively. In order to absorb the forces acting in the axial direction, i.e. to hold the fitting members 11 and 12 together, retention brackets are provided and they are not shown in Figures 1 and 3, one of which is described, for example, in EP 1 423 294 B1 Lt; / RTI >
To form the gear, an external tooth-shaped tooth 16 is formed on the second fitting member 12 and an internally-toothed tooth-shaped ring 17 is formed on the first fitting member 11 They are interlocked. The tip diameter of the external tooth-like arrangement of the toothed wheel 16 is smaller than the root diameter of the internal tooth arrangement of the toothed ring 17 by at least one tooth height. The corresponding difference in the number of teeth of the at least one toothed ring 17 and of the teeth of the toothed wheel 16 enables the rolling motion of the toothed ring 17 on the toothed wheel 16 do.
The second fitting member (12) has a bearing seat (29) concentrically with respect to the toothed wheel (16). The bearing seat 29 is formed as an extruded collar on the second fitting member 12 and is consequently integrally constructed thereon. In an alternative embodiment, the bearing seat is a bearing hole or is secured to the second fitting member 12 as a separate sleeve.
On the collar 19 of the first fitting member 11, two wedge segments 27 of the eccentric body are supported by their curved inner surfaces. The second fitting member 12 is supported by the curved outer surfaces of the wedge segments 27. To this end, the bearing seats 29 of the second fitting member 12 are anchored in a materially integrated manner and aligned with the planar bearing bush 28 with the outer surfaces of the wedge segments 27 abutting thereto.
An eccentric body for pressing the toothed wheel 16 is formed at the engagement position in the ring 17 in which the wedge segments 27 and the spring 27a for receiving the preliminary tension are made to abut against each other in the eccentric direction . When the eccentric body is driven by the drive shaft 7 in this example, the wedge segments 27 slide along the planar bearing bush 28, which displaces the eccentric direction and, as a result, Displacing the engaged position of the machined wheel 16, which may appear as a rolling motion, i.e. as a relative rotation with a superimposed swing motion between the first fitting member 11 and the second fitting member 12 . Whereby the inclination of the backrest can be adjusted between several positions for use in a stepless manner.
The planar bearing bush 28 is slot-shaped in this example, that is, the two ends of the cylindrical planar bearing face each other without any connection. In modifications of the embodiments, the ends are clinically held together or the planar bearing bushes are configured as non-slotted cylinders.
The flat bearing bush 28 is connected to the bearing seat 29 of the second fitting member 12 by a peripheral laser weld seam 31 at the end face of the first fitting member 11 and back. In modifications of the embodiment, the flat bearing bush 28 is connected to the bearing seat 29 by a laser welding seam at its end face towards the first fitting member 11, or at both end faces. As an alternative to the perimeter laser weld seam, the laser weld seam may comprise a plurality of segment partial seams.
The gears of the second embodiment (Figs. 4 and 5) are substantially configured in the same manner as in the first embodiment. However, the two fitting members 11 and 12 are constructed differently with respect to the connection to the seat member 3 and the back 4, in particular. However, due to functional similarities, they still have the same reference numerals as in the first embodiment.
The two fitting elements 11 and 12 are in the form of a substantially circular disc and are arranged in the form of a plurality of geometric shapes in the region of the outwardly oriented face thereof, Shoulders or cams. The peripheral ring 13 is provided to receive the forces acting in the axial direction, i.e. to hold the fitting members 11 and 12 together. Preferably, the perimeter ring 13 is rigidly connected to the second fitting member 12 and is welded in this example. By means of the radially inwardly oriented edges, the peripheral ring 13 is prevented from interfering with the relative rotation of the two fitting members 11 and 12 by means of a separate sliding ring, Which can be moved with respect to the ring. From a structural point of view, the two fitting members 11 and 12 thus form a disc-shaped unit with the peripheral ring 13.
The third embodiment (Fig. 6) corresponds to the second embodiment with respect to material integration of the planar bearing 28 with respect to the bearing seat 29, but the bearing arrangement for the fitting members is comparable to that of the second embodiment Can be reversed. The first fitting member 11 has a bearing seat 29 concentric with the toothed ring 17. A collar 19 is formed as an extruded collar on the second fitting member 12, i. E. It is integrally formed on the fitting member or is secured to the fitting member as a separate sleeve.
In a fourth embodiment (Fig. 7) corresponding to the third embodiment, except for the details of the material-integrated connection between the flat bearing bush 28 and the first fitting member 11, the plain bearing bush 28 Is laser welded to the bearing seat 29 of the first fitting member 11 by means of three, preferably and in this example three, abutment positions 33 distributed circumferentially at an angle of 120 [deg.] .
In the fifth embodiment (Fig. 8), the cylindrical basic shape of the planar bearing bush 28 has a thin wall thickness of less than 1 mm, in particular a wall thickness of approximately 0.5 mm, and has an inverted edge at each of its two axial ends . To this end, the two axial ends of the flat bearing bushing 28 are connected to each other by means of the bearing seats 29 after the assembly of the bearing seats 29 and after the laser welding seams 31 have been inserted between the flat bearing bush 28 and the bearing seats of the first fitting member 11 In particular in the radially outward direction after being manufactured between the first and second flanges 29, in particular beaded. The planar bearing bush 28 is thereby additionally connected to the bearing seat 29 in a positive locking manner and forms an axially bearing surface which is adjacent to the bearing seat 29, such as a carrier, Thereby reducing the operating torque of the fitting by ensuring the support function to minimize friction of one of the fitting members for the components.
In a modified embodiment, the planar bearing bush 28 has an edge that is inverted in the radially outward direction prior to assembly at a precise one axial end. After being introduced into the bearing seat 29, the opposite axial end is beaded.
The features, claims and drawings disclosed in the foregoing description may be important both individually and collectively in order to implement the invention into its various embodiments.

1 vehicle seat
3 sheet member
4 backrest
5 Handwheel
7 drive shaft
10 fittings
11 First fitting member
11a First flange area
12 second fitting member
12a second flange area
13 Peripheral ring
16 teeth machined wheel
17 Tooth-finished ring
19 colors
27 Wedge Segment
27a spring
28 plain bearing bush
29 Bearing sheet, extruded collar
31 Laser welding seam
33 Gabon Location

Claims (13)

1. A fitting for a vehicle seat,
A first fitting member 11, a second fitting member 12, and an eccentric portion rotatably supported,
On the first fitting member, a toothed ring (17) is formed,
On the second fitting member, a toothed wheel 16 is formed and engaged with the toothed ring 17, whereby the two fitting members 11 and 12 are connected to each other in a gear device manner,
The eccentric portion extends in a circumferential direction to drive the relative rolling motion of the toothed wheel 16 and the toothed ring 17, and the eccentric portion extends radially outwardly in the plane bearing bush 28 Respectively,
The flat bearing bush (28) is arranged in a bearing seat (29)
The plane bearing bush 28 has a wall thickness of less than 1 mm and is connected to the bearing seat 29 in a materialistic integrated manner by laser welding and the running side of the plane bearing bush 28 is coated ≪ / RTI >
Fittings for vehicle seats.
The method according to claim 1,
The bearing seat 29 is provided on one of the two fitting members 11 and 12 and the plain bearing bushing 28 is formed by a flat bearing bushing (not shown) which is the other of the two fitting members 11 and 12 28) is connected to the bearing seat (29) in the region of the end face of the bearing
Fittings for vehicle seats.
The method according to claim 1,
Characterized in that the plane bearing bush (28) is connected to the bearing seat (29) by means of a peripheral laser welding seam (31)
Fittings for vehicle seats.
The method according to claim 1,
Characterized in that the plane bearing bush (28) is connected to the bearing seat (29) by three abutment positions (33) distributed at an angle of 120 degrees around the plane bearing bush.
Fittings for vehicle seats.
The method according to claim 1,
Characterized in that the bearing seat (29) is secured to the first or second fitting member (11, 12) as a separate sleeve.
Fittings for vehicle seats.
The method according to claim 1,
Characterized in that the plain bearing bush (28) has a cylindrical basic shape and the two ends of the plain bearing bush (28) are facing each other in an unconnected state.
Fittings for vehicle seats.
The method according to claim 6,
Characterized in that the two ends of the plane bearing bush (28) face each other in an unconnected state.
Fittings for vehicle seats.
The method according to claim 1,
Characterized in that the plane bearing bush (28) has a wall thickness of 0.5 mm.
Fittings for vehicle seats.
The method according to claim 1,
Characterized in that one of the two axial ends of the plane bearing bush (28) is inverted in a radially outward direction,
Fittings for vehicle seats.
10. The method of claim 9,
Characterized in that one of the two axial ends of the plane bearing bush (28) is beaded in a radially outward direction,
Fittings for vehicle seats.
10. The method of claim 9,
Characterized in that both axial ends of the plane bearing bush (28) are inverted in a radially outward direction,
Fittings for vehicle seats.
12. The method of claim 11,
Precisely one of the two inverted ends is already turned over before the flat bearing bush 28 is mounted on the bearing seat 29. [
Fittings for vehicle seats.
13. A method of manufacturing a connector having a fitting according to any one of claims 1 to 12,
Vehicle seat.

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